Recording apparatus for recording gas concentrations in the atmosphere



Oct 7, 1952 A. o. BECKMAN ET AL 2,613,126

` RECRDING APPARATUS FOR RECORDING GAS CONCENTRATIONS IN THE ATMOSPHERE Filed Feb. 18, 194e 3 Sheets-Sheet l FOR THE F/RM ,4 fromm-V5 Oct. 7, 1952 A. O. BECKMAN ET AL RECORDING APPARATUS FOR RECORDING GAS Filed Feb. 18, 1946 CONCENTRATIONS IN THE ATMOSPHERE 3 Sheets-Sheet 2 FOR THE F IRM Arop/va ys Oct. 7, 1952 A. o. BECKMAN ET AL 2,613,126

RECORDING APPARATUS EOR RECORDING GAS CONCENTRATIONS 1N TRE ATMOSPHERE 5 Sheets-Sheet 5 Filed Feb. 18, 1946 Q, IIII .Amm

/Z/x/f/Vrops ARNOLD 0. 55C/(MAN, l dfi/W55 D. /VC Guam/GH.,

#App/5 /f/Ech: F05 TE/P A? HA/P/e/s.,

/PZEZ FCA THE F//PM /l Trop/v5 v5 whether se arated from each other, contacting each other, or somewhat overlapping. In this connection, it is an object of the invention to Contact side-by-side bands of a record member with a medium capable of producing a visible record or mark on the record member, the medium being quantitatively varied in correspondence with the variations of the phenomenon to be recorded.

A further object of the invention is to provide a novel record member of the indicator type with adjacent bands which can be individually discoiored by a variable medium, and in which the bands are separated to confine the action of the medium at a particular time to a single band.

Other objects of the invention lie in the provision of an intermittently operating mechanism with appropriate drives therefor, and which is capable of giving a series of measurements of a variable phenomenon.

A specific object of the invention is to provide a novel method and apparatus for accurate determination of minute concentrations of poison gases or other contaminating substances in the atmosphere. in this connection, it is an object of the invention to provide a device which will measure minute concentrations of acid-forming substances, typically organic compounds containing halogen, sulfur, or other substances which form acids or acid anhydrides upon heating in the presence or absence of oxygen.

Still further objects and advantages of the invention will be evident to those skilled in the art from the following description of an exemplary embodiment of the invention particularly designed for the measurement of minute concentrations of mustard gas in the atmosphere.

Referring to the drawings:

Fig. l is a top View of the device;

Fig. 2 is a side elevational view of the device, taken in the direction of arrow 2 of Fig. 1;

Fig. 3 is an end view of the device, taken as indicated by the arrow 3 of Fig. l;

Fig. 4 is a View of the operating mechanism of the device with the drum removed, and is taken substantially as indicated by the arrow 4 of Fig. 2;

Fig. 5 is a fragmentary end view of the device, partially in section, taken generally as indicated by the arrow 5 of Fig. 1;

Fig. 6 is an enlarged fragmentary view of a portion of the device as shown in Fig. 2, illustrating the drum and the operating tube of the invention;

Fig. 7 is a sectional view, taken along the broken line 1 1 of Fig. 6;

Fig. 8 is a sectional View of the pump of the invention, taken along the line 8-8 of Fig. 5;

Fig. 9 is a sectional view of the aspirator of the device; and

Fig. 10 illustrates a portion of the record member.

The measuring apparatus is indicated generally by the numeral Il and is herein exemplied as a self-contained unit, the power for driving the various units being derived from a pressured container i2 or a suitable clockwork I3, shown as covered by a closure It. The device is mounted on a base I5 carrying a vertical partition I6, and its mechanism is usually completely enclosed by a removable cover, not shown.

The pressured container l2 preferably contains a pressured fuel, typically a liquefied petroleum gas such as butane, which serves both to heat the sample stream of air and to draw this stream through the apparatus. As shown best in Figs. 1-3, the liquefied fuel flows through a manual control valve l1 through a small looped pipe I8 to a lter I9 and thence to a pressure regulator 2E, in accordance with well-known practice, the fuel expanding and vaporizing when a small fiow thereof passes through the Valve Il. The pressure regulator delivers a constant or regulated-pressure stream of the now-gaseous fuel through a rubber tube 2l to an aspirator 2S.

The aspirator 23 serves the dual function of mixing air with the fuel to form a combustible mixture delivered through a pipe 24 to a burner 25 and to aspirato a sample air stream through a quartz tube 26 and to move the treated air stream through subsequent equipment to be later described, this air stream entering the aspirator 23 through a connection 27. rlhe details of such an aspirator are best shown in Fig. 9. Referring thereto, the rubber tube 2| delivers a stream of the gaseous fuel to a nozzle with a small tip 28 terminating just above the connection 2'1 and discharging into a tapered throat 29 with which the connection 27 communicates to aspirate gases from the sample air stream into the throat 2S to mix with the fuel. The resulting mixture moves upward from narrow passage 3U at substantial velocity and flows past air-admitting openings 3l to aspirate air therethrough in amount sufficient to form a combustible mixture. The amount of air admitted through openings 3! is controlled by a sleeve 32 slidable on the pipe 24.

The fuel-air mixture enters the burner 25 and is expelled as a plurality of jets through burner openings 34, which are directed upwardly toward the quartz tube 26 to heat same. A U- shaped reflector extends beneath and on opposite sides of the burner 25 to concentrate heat rays on the quartz tube 26. The entire burner structure is surrounded by a burner housing 36 which carries the reector 35 and which is open at its upper and lower ends. The burner housing 36 provides aligned openings on opposite end walls through which the quartz tube 26 loosely extends, the housing 35-hanging on the quartz tube.

The quartz tube 26 provides an entrance end 37 open to the atmosphere to receive the initial aspirated sample air stream which enters as indicated by the arrow 38. This entrance end 31 is held in a clamping structure 39 which is, in turn, secured to a pivoted post 4E] to swing about the vertical axis of the post. In the illustrated embodiment, the post 40 pivots in a socket 4l and is surrounded by a clamp 42 which carries the aspirator 23 which, in turn, carries the burner 25. Correspondingly, the quartz tube 2B, the aspirator 23, the burner 25, and the burner housing 35 pivot together as a vunit about the vertical axis of the post 40.

If the sample air stream contains an acid-forming substance, such as mustard gas or any organic material which contains halogen, sulfur, or other substances which form acids or acid anhydrides upon heating, each substance will be converted into an acid or acid anhydride when passing through the heated section of the quartz tube 26. Thus, mustard gas will be converted into the corresponding hydrogen chloride and other products.

The resulting modified air stream then passes through a U-shaped operating tube 43, best shown in Figs, 2, 6', and '7, and which may be a bent continuation of the quartz tube 26. In this operating tube, the modified stream is made to contact .a .receptive .medium which willy absorb or react vwith .the .acid .or acid anhydride. In the illustrated embodiment, this medium is shown as .a small body 4of liquid, typically distilled watenxin- .dicated by the .numeral 4,4, which only partially lls the bottom of .the U-shaped operating` tube 43, as suggested in Fig. 6.k Such a body of water 44 presentsa relatively extensive surface fory contact with the ,modied air stream flowing through -a narrow space .45. In measuring concentrations o f mustard gas, when using abody 440i distilled water, this water will progressively absorb the bye drogen chloride and other products of the Inedivlied air stream and will become progressively more acidic substantially in proportion .to the amount of the ,modified stream flowing in contact therewith and the amount of the hydrogen'oihloride and other products therein. The aciditycr p H of .the body `of water .44, after the lapse of any predetermined time, will thus be a `measureof the concentration .of mustard gas in the surrounding atmosphere.

The spent gas of .the mddied stream moves vfrom the operating .tubed through a rubbertube l.

-48 toa liquidtrap 4.9, bestshoyvn in Figs. 1 and 2, from whence it flows toa flow meter 50 .and thence through a rubber tube 5l to the connection 21 whereby the spent .gases lare mixed with .the fuel and any'residual .substances .tend to be burned. The flow meter 50 may be of the'rotameter .type in `which a small vball 5 2 is lifted in a tapered passage .of a transparent .tube to a height. indicative vof the lnow rate, the Atube being calibrated .or carrying a .single calibration mark to indicate `the correct flow rate. In practice, with an instrument of the .type exemplified, a flow rate .of

about o-.500 `nil/min. will usually be found satisfactory. This flow rate is lcontrolled .by adjustment .of the valve Il so .that s imultanecuschange in fuel and flow rate oi .ai-r is effected by .a single adjustment, whereby .the increased heating required by an increase in the sample .stream automatically obtained. Usually, however, it is preferable to set the valve .Il for .a pre-selected rate-of owof thesam-ple streamasmcasuredby the flow meter..

While various methodscan be used lfor determining `the acidity or pH ofthe body of .water .44, we prefer to expel this body ,of water .and measure .its acidity :by .use .cia record member '55 wrapped around adrum '56 andheldfin place to .completely encircle the drum Aby use of a removable strip A51, best shown in Fig. 5, and latching into avlatch member `5.8 to ,compress `the ends .of the ,record member 5.5 against the drum. The record mem- .ber 5.5111215 be .a blotting paper impregnated ,with

an indicator, typically Conso red, the .record member preferably .being banded ,as hereinafter described. L

Expulsion ofthe body of .acidic Water .44 .onto the record member .55 ,to produce `.a visiblerecord is best accomplished through Y use of .a small cap.-

illary passage .59 formed in a.. fluid-expelling member, shown as a .curved spout 5,0 at the bottom ofthe operating :tube 43, the spout .providing vva ground face .6l :adapted to ensagf? the record .member .55 when the `l operating Atube-.d3 is rin its full ,line position o f Fig. 7. This .operating ltube 43 :swings with Vthe .quartz tube 2S about .the yertical axis of the post d0 `to vbe .displaced into Athe dotted line position .62 .of Fig. 7. The -.operating .tube .43' .assumes this dotted line position .during .acidiicationof thebody .of water 44, .the capillary .size of the passage 59 preventing gravitational drainage of the water therefrom. If, however, the

operating tube is .moved into licht percussive contact with the .record member 5,5., the sudden .Stop- .pase and the absorptive. nature ofy the record member 5.5 will drain or .expel the acidic Water slowly from the well provided at the bottom of the operating tube 43.

,As the. acidic water .is absorbed by the record .member 55 the indicamrv therein will react With the .acid to discolor the .record member ,and produce a visible record 0r mark. 4In the absence of the banding .of the record member hereinafter doscribed. the resulting discoloration will extend radially substantially equal distances from the zone Aof Contact with the ground face 6I and the radial extent of discoloration willbe a measure of the acidity. or pH of the Water body 4d. now completely drained from the operating tube (i3, and

also will be a vmeasure o f the mustard ses or other substancewhioh was modified 'by heat to result the acidification. record member l55 will be wetted' in a zone beyond the discoloratioait being clear that the acid ,is neutralized by Jthe Congo red and, after neutralization, the residual Water will be absorbed an outer cone, although this outer zone wili'not be discololed because no acid isv present in the solution absorbed 4thereinto.

.On the other hand,` it is distinctly l preferable to confine 'the .discoloration to a Anarrow transverse band of the record member '55. A lbanded .record member having 'handy-isolatingtransverse linesv is suggested in 'Fi g;gl0 and-can be ,made by marking, coating, orsprayi-rig the 'lines-with a non-wettable substance which will isolate the wettingof the record "member to the intervening '.bands. yThe preferred method of banding-involves spraying lacquer througha suitable mask onto 'the record vmember 55 in upperand lower zones 6,3 and 64; also, ini transverse zonesy d'5 which form the band-isolating lines Aand which are separated from each other to leave bands de ofthe record member uncoated. n

-With thisarrangernent, if the drum 56 is 4turned so thatthe ground .face 6l contacts one of vthe uncoatedbands `lilithe discoloring action ofthe acidic Water will be confined to this band and the Alength O discoloration will be a function of the acidity. By proper risolationhof the bands et, there will be no sidewis'e absorption tending to discolor .adjacent bands. Thus, if the body of water 44 is -periodically renewed and each body of `water is displaced Onto a separate band 66, a series of side-by-siderecords or marks will appear on .adjacent bands and the extremities or limits of the' discolored portions will represent the d ifferent acidities and also the different concentrations of mustard gas or ,variations in concentration' of .Suchgds An attempt has been made in Fig. Al0 lto show three successive bands 66 omfdifferent length, represented respectively by dimens sional arrows '61 '5 8, and ,59 .between the extremities thereof. Wetting of each band' will extend beyondv the discoloration. Ihe length of each -band may be directly measured .as `an indication o f the concentration ,in 'question but, for most .accurate results, reference should 'be had to cali- `b ration tables which can ybe worked out for differentlengths of wetting toshow theexact concentrations corresponding to thelengthl -oi ldiscoloration,v even ,though the concentrations` be low, such as 0.15 gamma of mustard r gas per .liter .of air.- Qf .ooursaif the volumolof the body ci Water .'44 is exaotlyjtho same with each roneWal, the extent Ao f wetting .will ,also bathe same. However, slight variations in the volume of the water body are often encountered and can be compensated for bytables for each length of wetting and `.showing the concentration corresponding to the length of discoloration., VWhile the present embodiment shows theground face as contacting the record member near the center of an exposed transverse band 66, in which event discoloration will progress upwardly and downwardly, this is not essential. If desired, the ground face e! can contact the upper orl lower end of such exposed band, in which event discoloration will progress in only one direction.

The illustrated embodiment includes automatic means (l) for moving the `drum 56 step bystep to bring adjacent bands 66 opposite the capillary passage 58; (2) for intermittently 're-charging the operating tube 43 with the body of water 44; and (3) for intermittently moving the operating tube 43 through a cycle in which its two extreme positions are shown in Fig.- '7. Such means are controlled by the clockwork i3 lwhich' vcan be wound by a key applied to a squared shaft i8 of Fig. 4. The details of. the clockworkrare not illustrated. Suffice it to say that this'clockworI-z drives a gear 'H at a constant speed when'a startstop lever 'l2 (Figs. 4 and 5) is shifted to a"start position.

The mechanism for advancing the drum 58 step by step includes a second gear T3. meshing with the gear and rotating a vertical shaft 'I4 journalled in a tubularrextension of aplatemember i5 carried on posts 'i6 of the base l5. This shaft '15', carries an angularly-adj'ustable, multi-lobe lower cam 'VI resiliently engaged byl a follower lla of an arm 78 pivoted by a leaf spring l5 attached to the plate member T5. The free end of the arm 1S is connected by a leaf spring 88 to an operating member 8| which carries'a ratchet member 82, movable therewith and advancing a ratchet wheel 33Y tooth by tooth. Another ratchet member 84 is fixed to the plate member 'i5 to prevent reverse motion of the ratchet wheel 88. In this manner, the ratchet wheel is turned tooth by tooth in the direction of arrow 85. This ratchet wheel 83 isV carried by a shaft 35a which is pivoted relative to the plate member 75 by extending into a bore of a boss 85h thereof. The shaft 85a carries a circular plate 88 on which the bottom of the drum 58 rests. A pin 81 of the plate 88 extends into a corresponding opening distance between the teeth of the ratchet wheel i 83 is equal to the angular distance between bands (i8 of the record member. The follower 17a of the arm 78 is limited in its motion toward the faces of the cam ll by engagementrbetween the ground face 6| and the record member 55, as will be later described. Such engagement acts as a stop means and holds the follower 'lla from the faces of each lobe of the cam 'H during a portion of each revolution of the cam, wherefore the drum 58 is stationary during such fractional rotation, after which the follower engages the surface of the cam,`later movement to the crest of the cam turning the ratchet wheel 83 one notch. After the follower 'lla passes the crest of the cam, it drops quickly into the succeeding notch of the cam and the ratchet member 82 moves rearwardly to engage the next tooth.

lThe mechanism for moving the operating tube :i3 between its two positions shownin Fig. 7 is operated by the aforesaid reciprocation of the operating member 8|. As best shown in Fig. 4, the forward end of this operating member 8| is joined by a spring member 88 with a clamp structure 88 adj'ustably connected to a vertical member 9D pivoted Aat its lower end to swing parallel to the partition |6. For example, the lower end of the vertical member 98 is connected to a journal member 9| (Fig. 2) pivoting on a horizontally disposed screw member 92. The clamp structure 89 is adjustable vertically on the vertical member 9D to vary the lever arm. It provides also nuts 93 (Figs. 4 and 5) for adjustment of the angle between the vertical member ed and the operating member 8|. I A

l The upper end of the verticalv member 943 provides a tongue 94 cooperating with a notch v95 of an adjustable member 9S to form a space receiving the quartz tube 28 near its junction with the operating tube 43. The lvertical member 90 thus provides a hinged support for the quartz tube at this point.

It will be apparent that the vertical member 9,8 reciprocates with the operating, member 8| and, in doing so, it carries the operating tube 43 between its two positions shown in Fig. 7. Rearward movement of the upper end of the vertical member is limited by engagement between the ground face 6| and the record member 55 to form the stop means previously described. When the operating member 8| advances forwardly, it swings the vertical member 9B forwardly and moves the operatingtube 43 to its dotted line position E2 of Fig. 7. From the mechanism thus far described, it will be apparent that the ground face 5| will be moved from'engagement with the record vmember 55 as soon'as'the follower 'Via of the arm 18 engages the surface of a lobe of the cam '|`|.A Further movement of the cam moves the operating tube 43 slowly toward its dotted line position and, during this cycle of the operation, the gas sampleis acidifying'the body of water 44. Also during this portion of the cycle, the drum 5B isadvancing to present a new band to the recording position adjacent the ground face 5|. As soon as the follower lla moves from the crest of the lobe of the cam the operating tube 43 moves quickly toward the record member 55, the ground face 6| contacting same with a slight percussive action sufcient to start drainage of the body of water. The operating tube 3. remains stationary in this position, to permit complete drainage of the body of water 44, until the follower 'Ila of the arm 'f8 again engages the next lobe Yof the cam The means for intermittently renewing the body rof water 44 includes a small spring-actuated pump |80, best shown in Fig. 8 and released by the clockwork |3 in a manner best shown in Figs. 4 and 5. Referring to the latter gures, the shaft '|'4 carries an upper cam |8| which is adjustable in angular position relative to the shaft and which provides a number of lobes equal to the cam 1l. The sole function of the upper cam lili is to cock and trip the pump |80. This upper cam is engaged by a follower 82 of a pump-operating arm |83 which is moved longitudinally by the cam. A rear portion of the arm |03 is carried by the free end of a spring |84 whose other end is connected to the plate member '|5. This spring not only guides the arm |83 but exerts a resilient pump-actuating pressure thereon. Theforward end of the arm |83 is connected to one arm of a bell crank |05 pivoted at |86. The other arm |07 of the bell crank carries a stroke-adjusting screw |08 and extends between bifurcations |09 of a pump plunger IIO 'to which it is pivotally connected. As the pump-operating arm. |03 is drawn rearwardly by thefollower |02 risingon a lobe of the cam IOI, the plunger AI;I-.0is raised to or above the position shown in Eiga.' As soon as the follower drops from the crest of this lobe of the cam, the spring |04 v-forces the plunger |110 quickly downward.

VThe plunger I I reciprocatesfina cylinder `.I II of va pump body I I2. -A small :entrance lport ;I I3 admits water to the 4cylinder III when .the plunger `I I 0 is raised. lThis -wateris contained in a reservoir I I5 supported beneaththe platemember -1-5fby1a saddle I I6, the` reservoir being fiilled from time vto time throughopening I I1 ...'(Eigafc) When the plunger I-I0 lowers under thexactionof the spring I 04,11; closesA the entrance port i Iilfland displaces fa meteredquantityiofwvater iffromithe cylinder l II I throughan exitfpassage lligand a smallrubber hose I I 9 Iin-tdaneck I 20 o'ffthe-foperating itube-43. The ne'ck l |20 Ipreferablyr'opens on the operating tubeataposition slightlytia'bove the normal water f level tlfiereinfV asl-best shown.. in Fig. 6. Correspondinglyf-suchfdownwardtmovement of the plunger l|7170 ydisplaces a v.metered amount of waterinto the now-#drained operating tube 433.` vvThe amountof waterirequiredtis .v-ery small and needbe no more thana fewdrops.

The timing of the pumpisisuch thatf.the.new incrementof water is delivered @toV the operating tube I43` onlyafter completeldrainage of theepreviously-'contai-ned acidifled water. l Normally,f.the pump Ais timed -to dischargeraz-:new increment promptly afterfthe ground face Ilseparatesirom therecord member-*55.

While a completely automatic mechanism .has been shown, it should be understiod that the invention is not limited thereto. Nor is it limited to the making of a recordfextenning overiaprolonged time, e..g.,. 1211er; 241.hours, as impossible with the illustrated. embodiment. In itsbroader aspects, the invention comprehends discoloration or otherwise forming records or marks in side-byside bands of a' record-memberfif 'theireco'rdgis to show the variationsV over a'prolongedfperiod-of time. In other instance;fofcourseftheinvention canbe used for individual tests andineedinot-be automatically operating.'

It should be clear, also, that the invention is not limited to the measurement of mustard gas. It is equally applicableto the measurement of other halogen-containing compounds or other substances which form acids or acid anhydrides upon heating, whether the heating is in the presence or absence of oxygen. In this connection, the invention can be employed to measure sulfur content but, in thi-s instance, greater sensitivity can be obtained by disposing within the heated quartz tube 26 a catalyst, such as platinum foil, aiding the production of acids or -acid anhydrides.

Furthermore, while the invention has been exemplied with reference to systems in which the medium or body `of water 44 becomes progressively more acidic, it should be clear that the device is useful also in other measurements in which such medium becomes progressively more alkaline. In the latter event, a diierent indicator will be used in making the record member 55 but the same general principles apply and discoloration can be measured as an indication of the concentration of a substance, or, in fact, as an indication of variations in various phenomena. For example, the phenomenon to be measured can be made to change the acidalgemeene .for sperati/ely.' 'ennesima Se ity or alkalinity, e. g. `the pH or hydrogen ion concentration, of a .medium such as the bedr Q f water ..431 and :the kdepbiligll..1143 fr-0.111 ,1,1mit!lity can be measured,- i. le., indicated ,or recorded; by using the principles .-of' :the 'present .i,I.1.Y..er1.e1,L Thus, ammonia or amines; either free or resulting from-thermal decomposition, can be made t@ modifyafmediumwhichisthenapplicato e Suit',- -able record :member :to .Obtain @ih-e desi d m crement. addition. ,indicators other than 13e pris-responsive type ,can ibe insee? :F.rgeimnla measurements can kbe made using 56,1) starch.- iodide paper :reacting with lialeeens f0.1 ,other oxidizing lasen-t; @.29 dead neet-ate .eener reggiiHe-:Wiib bvdrgsenasuliider) efc :The words, EdslQri f9.1 fssgelelain .ere -Spec'c tion and y spacekfor rec ivmg" said. IljuidQmedium; actueiiesrmeenlio'me meterle, fluidi-smelling 1 mem Ver towardanda `iromjsaid.remord' 'linemlber to.translfe lzdwffluid Iryiediiini,ffiik "S'said caring a;

nulagertsuing,meintenrosato,recorrida` 2. In a device for recording at a recording stationavariablephenomenon by use of a record vmember lproviding.side-by-side transverse bands, each band containing an indicator chemically reactive with a chemical-containing uid medium to produce a change in appearance of the record member in the zone of such reaction, said bands of said record member being fluid-isolated from each other to prevent fluid applied to one band from reaching an adjacent band, the amount of chemical in said fluid medium varying from time to time with the phenomenon to be recorded, the combination of: means for moving said record member relative to said recording station to present said bands successively to said recording station; a uid'- expelling member providing a space for receiving said fluid medium; actuating means for` moving said fluidfexpelling member into and out of duid-transferring relationship with said record member to successively transfer an increment of said iiuid medium from said iiuidexpelling member to said rec-ord member; and means for operatively connecting said means for moving said record member -and'said actuatingr means to apply said increments of said fluid medium to successive bands of said record member.

3. A device as defined in claim 2, in which said means for moving said record member relative to said recording station includes a drive means 1 Y v11. and `means for intermittently connecting said drive means to said record member to advance said record member step by step to present said bands successively to said recording station, and in which said actuating means includes means operatively connected to said drive means for moving said duid-expelling member toward and away from said record member, and in which said operatively connecting means includes means for timing the movement of said fluid-expelling member and the step-by-step advancement of said record member to bring the former into fluid-transferring relationship with the latter between periods of advancement of the latter.

4. In a device for recording at a recording station a variable phenomenon by use of arecord member providing side-by-side transverse bands, each band containing an indicator chemically reactive with a chemical-containing fluid medium to produce a change in appearance of the record member in the zone of such reaction, said bands of said record member being uid-isolated from each other to prevent iiuid applied to one band from reaching an adjacent band, the amount of chemical in said iiuid medium varying from time to time with the phenomenon to be recorded, the combination of: means for moving said record member relative to said recording station to present said bands successively to said recording station; a uid-expelling member providing a space for receiving said fiuid medium and providing a small passage communieating with said space and providing an endl ARNOLD o. BECKMAN. JAMES D. MCCULLOUGH.

12 REFERENCES CITED The following references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date 387,936 West Aug. 14, 1888 462,504 Olan Nov. 3, 1891 562,834 Knauss et al June 30, 1896 691,249 Dieterich K Jan. 14, 1902 728,022 Schultze May 12, 1903 749,305 Lenot Jan. 12, 1904 904,310 Cole Nov. 17, 1908 1,012,639 Holmgren Dec. 26, 1911 1,044,835 Wattles Nov. 17, 1912 1,063,091 Wever May 27, 1913 1,205,724 Fairiie Nov. 21, 1916 1,216,303 Freeman Feb. 20, 1917 1,560,660 Cain Nov. 10, 1925 1,719,864 Zimmerman July 9, 1929 1,755,793 Peters Apr. 22, 1930 1,919,861 Rodhe July 25, 1933 1,943,684 Martin et a1 Jan. 16, 1934 `1,960,465 Thomas May 29, 1934 1,967,895 Marvin July 24, 1934 2,088,683 Babson Aug. 3, 1937 2,105,226 Pratt Jan. 11, 1938 2,153,568 Johnson Apr. 11, 1939 2,174,349 Littlefield Sept. 26, 1939 2,181,533 Kline et a1 Nov. 28, 1939 2,230,593 Hassler Feb. 4, 1941 2,232,622 Moses et al Feb. 18, 1941 2,236,373 Kowalski Mar. 25, 1941 2,345,090 Brace Mar. 28, 1944 2,422,852 Ratcliie June 24, 1947 FOREIGN PATENTS Number Country Date 460,108 Great Britain Jan. 21, 1937 517,462 Great Britain -Jan. 31, 1940 OTHER REFERENCES pages 260-263, July 15, 1936.

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Chem. Ind., vol. 18, page 551, 1940. 

